MCR3U Polynomials Exam Review PDF

Summary

This document provides an overview of polynomials. It covers different types of polynomials, such as monomials, binomials, and trinomials. It also describes the concept of polynomial degree and factoring techniques.

Full Transcript

MCR3U Exam Review 1

Polynomials

A polynomial is an algebraic expression with real coefficients and non-negative integer exponents.

A polynomial with 1 term is called a monomial,.
A polynomial with 2 terms is called a binomial,.
A polynomial with 3 terms is called a trinomial,.

The degree of the polynomial is determined by the value of the highest exponent of the variable in the
polynomial.
e.g. , degree is 2.

For polynomials with one variable, if the degree is 0, then it is called a constant.
If the degree is 1, then it is called linear.
If the degree is 2, then it is called quadratic.
If the degree is 3, then it is called cubic.

We can add and subtract polynomials by collecting like terms.
e.g. Simplify.
The negative in front of the brackets
applies to every term inside the brackets.
That is, you multiply each term by –1.

To multiply polynomials, multiply each term in the first polynomial by each term in the second.

e.g. Expand and simplify.

Factoring Polynomials

To expand means to write a product of polynomials as a sum or a difference of terms.
To factor means to write a sum or a difference of terms as a product of polynomials.

Factoring is the inverse operation of expanding.

Expanding 

 Factoring
Sum or
Product of
difference of
polynomials
terms
MCR3U Exam Review 2

Types of factoring:

Common Factors: factors that are common among each term.
e.g. Factor,
Each term is divisible by.

Factor by grouping: group terms to help in the factoring process.
1+6x+9x2 is a perfect
e.g. Factor, Group 4mx – 4nx and square trinomial
ny – my, factor each
group
Difference of squares

Recall n – m = –(m – n)

Common factor

Factoring
Find the product of ac. Find two numbers that multiply to ac and add to b.
e.g. Factor,
Product = 14 = 2(7) Product = 3(–6) = –18 = –9(2)
Sum = 9 = 2 + 7 Sum = – 7 = –9 + 2
Decompose middle term –7xy
into –9xy + 2xy.
Factor by grouping.

Sometimes polynomials can be factored using special patterns.

Perfect square trinomial or
e.g. Factor,

Difference of squares
e.g. Factor,

Things to think about when factoring:
 Is there a common factor?
 Can I factor by grouping?
 Are there any special patterns?
 Check, can I factor ?
 Check, can I factor ?
MCR3U Exam Review 3

Rational Expressions
For polynomials F and G, a rational expression is formed when.

e.g.

Simplifying Rational Expressions
e.g. Simplify and state the restrictions.
Factor the numerator and denominator.
Note the restrictions.

Simplify.

State the restrictions.

Multiplying and Dividing Rational Expressions
e.g. Simplify and state the restrictions.

Factor. Factor.
Note restrictions. Note restrictions.

Invert and multiply.
Simplify.
Note any new restrictions.

State restrictions. Simplify.

State restrictions.

Adding and Subtracting Rational Expressions
e.g. Simplify and state the restrictions.
Factor. Factor.
Note restrictions. Note restrictions.
Simplify if possible. Simplify if possible.

Find LCD.
Find LCD. Write all terms
Write all terms using LCD.
using LCD.

Add. Subtract.
State restrictions.
State restrictions.

Note that after addition or subtraction it may be possible to factor the numerator and simplify the
expression further. Always reduce the answer to lowest terms.
MCR3U Exam Review 4

Radicals

e.g. , is called the radical sign, n is the index of the radical, and a is called the radicand.
is said to be a radical of order 2. is a radical of order 3.

Like radicals: Unlike radicals:
Same order, like radicands
Entire radicals: Different order Different radicands
Mixed radicals:

A radical in simplest form meets the following conditions:
MCR3U Exam Review 5

For a radical of order The radicand contains The radicand contains The index of a radical
n, the radicand has no no fractions. no factors with must be as small as
factor that is the nth 3 3 2 negative exponents. possible.
power of an integer.   1
2 2 2 a1 
a
6
 1 a
22  
a a
6
 a
22 
Simplest a2
6 form Simplest
 a form
2 
a
 MCR3U Exam Review 6

Not
simplest
form Simplest form

Simplest form

Addition and Subtraction of Radicals
To add or subtract radicals, you add or subtract the coefficients of each radical.

e.g. Simplify.
Express each radical in simplest form.

Collect like radicals. Add and subtract.

Multiplying Radicals

e.g. Simplify.
Use the distributive property to expand

Multiply coefficients together. Multiply radicands together.

Collect like terms. Express in simplest form.
MCR3U Exam Review 7

Conjugates Opposite signs
are called conjugates.
Same terms Same terms

When conjugates are multiplied the result is a rational expression (no radicals).
e.g. Find the product.

Dividing Radicals

e.g. Simplify.

Prime Factorization
e.g. 180
Factor a number into its prime 3 60
factors using the tree diagram
6 10
method.
2 3 2 5

Exponent Rules

Rule Description Example
Product
Quotient
Power of a power
Power of a quotient

Zero as an exponent
Negative exponents

Rational Exponents
MCR3U Exam Review 8

e.g. Evaluate. e.g. Simplify.

Follow the order Power of a quotient.
of operations.
Evaluate
brackets first. Power of a product.

Solving Exponential Equations
e.g. Solve for x.
Add 8 to both sides. When the bases are
Simplify. the same, equate the
exponents.
Note LS and RS are powers of Solve for x.
9, so rewrite them as powers
using the same base. Don’t forget to check your solution!

Functions

A relation is a relationship between two sets. Relations can be described using:
an equation an arrow diagram a graph a table
g
2
x y
8 -1 1 2
in words 0 7 2 3
“output is three more than input” 6 -3 3 4
3 -5 -2
4 3
a set of ordered pairs

function notation

The domain of a relation is the set of possible input values (x values).
The range is the set of possible output values (y values).

e.g. State the domain and range.
A: B: 4 Looking at the graph we C:
Domain = {0, 1, 4} can see that y does not go
What value of x will
Range = {2, 3, 8} below 0. Thus,
2
make x – 5 = 0? x = 5
Domain = R
The radicand cannot be less
Range =
than zero, so
Domain =
Range =
MCR3U Exam Review 9

A function is a special type of relation in which every element of the domain corresponds to exactly
one element of the range.
and are examples of functions. is not a function because for every value
of x there are two values of y.

The vertical line test is used to determine if a graph of a relation is a function. If a vertical line can be
passed along the entire length of the graph and it never touches more than one point at a time, then the
relation is a function.
e.g. A: 4
B: 4
This passes The line passes through
the vertical more than one point, so this
2
line test, so 2
relation fails the vertical
it is a line test. It is not a function.
function.

Inverse Functions
The inverse, , of a relation, , maps each output of the original relation back onto the
corresponding input value. The domain of the inverse is the range of the function, and the range of the
inverse is the domain of the function. That is, if , then. The graph of
is the reflection of the graph in the line.

e.g. Given.
Evaluate. Evaluate
You want to find the value of
Replace all the expression. You
x’s with –3.
are not solving for.
Evaluate.

Determine. Evaluate

Rewrite as If you have not already determined
do so.
Interchange x and y.
Solve for y. Using , replace all x’s with 2.
Evaluate.

4 4 4

1
y  f ( x)
e.g. Sketch the graph of the inverse of the given function
2 2. 2

Draw the Reflect the
line y = x. graph in the
line y = x.

y  f (x)
-2 -2 -2

-4 -4 -4
MCR3U Exam Review 10

The inverse of a function is not necessarily going to be a function. If you would like the inverse to also
be a function, you may have to restrict the domain or range of the original function. For the example
above, the inverse will only be a function if we restrict the domain to or.

Transformations of Functions
To graph from the graph consider:
a – determines the vertical stretch. The graph is stretched vertically by a factor of a. If a < 0
then the graph is reflected in the x-axis, as well.
k – determines the horizontal stretch. The graph is stretched horizontally by a factor of. If
k < 0 then the graph is also reflected in the y-axis.
p – determines the horizontal translation. If p > 0 the graph shifts to the right by p units. If p < 0 then
the graph shifts left by p units.
q – determines the vertical translation. If q > 0 the graph shifts up by q units. If q < 0 then the graph
shifts down by q units.
4

When applying transformations to a graph the stretches and reflections should be
applied before any translations. 2

e.g. The graph of is
transformed into -2. Describe the
transformations. -4

First, factor inside the 4
4

Shift to the Shift up by 1.
brackets to determine the right by 2. 2

values of k and p.
2

There is a vertical stretch of This is the graph of
-2
-2

3. -4 -4

A horizontal stretch of.
The graph will be shifted 2
units to the right.
e.g. Given the graph of
sketch the graph of
4
4

2
2

Stretch vertically Reflect in y-axis.
by a factor of 2.

-2 -2

-4 -4
 4

a>0
Quadratic Functions 2

minimum
The graph of the quadratic function, , is a parabola. -5 5

When the parabola opens up. When the parabola opens down. maximum
-2

a 0. The period of is , k > 0.
The value of b determines the horizontal translation, known as the phase shift.
The value of d determines the vertical translation. is the equation of the axis of the curve.
e.g. e.g.

gx = cos2x+1
2 1

1.5
0.5

1
gx = 0.5sinx+45
0.5
50 100 150 200 250 300 350 400

50 100 150 200 250 300 350 400 -0.5

-0.5

fx = sinx
-1
fx = cosx -1